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Screen printing is an extremely versatile means of reproducing a 2-D image onto a variety of objects.  Hand-drawn, painted, photographic and digital images can all be used singularly and in combination with each other.  Preparation and processing is relatively simple and multiples can be produced quickly. In this class, we will print with non-toxic, water-based inks.

For students doing work-study or internships, we will focus on three core areas of professionalization. First, each week will journal our work weeks, discussing and sharing our work experiences in a round-table. Second, we will build our professionalization skills, especially networking (in person and on LinkedIn), resume writing, and doing practice interviews. Finally, we will work on writing 5-year plans, to help us figure out where we’d like to be a few years after graduation. More specifically

The large-scale consumer web has been defined by epochs. The first epoch was defined by the user as consumer: large companies created content which was consumed by the masses. The second web epoch (web 2.0) has been defined by consumer creators, large companies own and deliver content created by users to other users (Facebook, TikTok, Snapchat, Twitter, Instagram, …). The third web epoch is—if you believe the hype—to be defined by self-ownership of content.

This course will serve as an introduction to working with circuits in a lab setting. We will learn about the relatively simple rules necessary for working with analog circuits and how those rules can be used to build objects of growing complexity. We will then move on to understanding how to build circuits that can measure properties of and interact with their surroundings.

This course offers an immersive experience into the world of DNA, genes, and genomes in eukaryotic organisms.  In addition to getting a grasp of the foundational biology, students will engage with various online databases and resources, becoming familiar with the computational algorithms and methodologies used to mine and analyze the ever-increasing data generated from whole-genome sequencing, and consider how that improves our understanding of evolutionary relationships amongst organisms based on their molecular fingerprints.  In the second half of the term, students

Research questions in cell biology and biochemistry often require the ability to study the proteins at the heart of the inquiry.  This course will give students hands-on experience quantifying proteins, detecting protein expression, measuring enzymatic activity, assessing protein-protein interactions, purifying proteins, and visualizing fluorescently-labeled proteins in vivo.

This course is an introductory level print media and drawing class. Students will learn about relief printmaking through demonstrations of techniques, hands-on experience, and critiques. Techniques include but are not limited to wood cut and linoleum cut. With this simple process, we will be able to explore color printing in depth. This course is also an introduction to making 2D images and the study of visual language. Students who have experience beyond the introductory level are welcome.

This course is an introduction to unique prints, or prints that are not necessarily printed as an edition. We will emphasize the making of mixed media prints using a broad range of methods from monotypes to digital prints. The class is structured around a series of projects where rigorous experimentation is encouraged.

This rigorous course provides a comprehensive introduction of the nervous system, including its structure, function, and development. Students will explore the principles of the cellular and molecular mechanisms that allow neurons and other specialized nervous cells to detect, encode, and transmit information; including signaling, synaptic transmission, and neuroplasticity.

How do we organize data to solve complex problems efficiently? This course studies the fundamental structures and algorithms that form the cornerstone of computational problem-solving. Building upon the programming foundations established in CS1, we will explore how algorithmic thinking and sophisticated data organization enables us to tackle increasingly challenging computational problems.

Have you ever wondered what a computer is and how it actually works?  In this course, we’ll answer the hardware half of this question.

Scanning electron microscopes are a fundamental tool in the physical and life sciences. When equipped with an X-Ray spectrometer, a SEM can provide rapid physical and chemical data of specimens on extremely small scales. This class with cover the theory and practical applications of SEM imaging and analysis for advanced science students who have their own research interests. Students will be expected to develop and conduct an independent research project through this class.

Together with calculus, linear algebra is one of the foundations of higher-level mathematics and its applications. This is NOT just the algebra you know from high school. There are several perspectives one can take on linear algebra: it is a method for handling large systems of linear equations, it is a theory of linear geometry (including in dimensions larger than three), it is matrix algebra, and it is a theoretical structure that appears throughout mathematics, physics, computer science, and statistics.

In the eighteenth and nineteenth centuries, mathematics underwent a vast expansion, into new, exciting, and increasingly counter-intuitive realms. The subject risked mystification and mutual incomprehensibility between experts in different sub-fields. In the first part of the twentieth century, a group of French mathematicians, under the pseudonym Bourbaki, undertook an ultimately successful program to use the foundation of set theory to put all of mathematics onto a common conceptual and logical foundation.

Bennington’s campus supports beautiful examples of temperate deciduous mixed hardwood forests. This class is a deep dive into forest ecology, land use change, and forest succession at a local scale. Students will explore the local forest community composition, structure, and function over the last 15,000 years and discuss the environmental conditions, disturbance dynamics, and biotic interactions responsible for the forest we have today.

Evolution is the unifying theory of biology, explaining the diversity of life on Earth and the mechanisms that drive adaptation and speciation. This course will explore the core principles of evolutionary biology, including natural selection, genetic drift, gene flow, mutation, and the interplay between evolutionary processes and ecological contexts. We will examine key evolutionary events, from the origins of life to the development of complex traits, using case studies across diverse taxa.